Systems and methods for generating ethernet modules based on base designs

ABSTRACT

Systems and method for generating Ethernet modules based on base designs. After a processor receives a base design for an industrial device assembly, the processor may calculate electrical load limits for sections of the base design based on dimensions of the sections, a number of sections, a location of the industrial device assembly, and the like. Based on the electrical load limits, the processor may determine a number of Ethernet modules for the sections and respective placements of the Ethernet modules within the base design. The processor may update a layout of the industrial device assembly based on the number of Ethernet modules for the sections and respective placements of the Ethernet modules within the base design.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims priority to and the benefit of U.S. ProvisionalApplication Ser. No. 62/937,036, entitled “AUTOMATICALLY GENERATINGSCALABLE SINGLE-LINE DRAWINGS IN REAL TIME,” filed Nov. 18, 2019, aswell as U.S. Provisional Application Ser. No. 62/937,093, entitled“SYSTEM AND METHOD FOR GENERATING A MOTOR CONTROL CENTER LINEUP BASED ONA LOAD LIST,” filed Nov. 18, 2019. These U.S. Provisional Applicationsare hereby incorporated by reference in its entirety for all purposes.

This application is related to co-pending U.S. patent application Ser.No. 17/035,651, entitled “SYSTEMS AND METHODS FOR GENERATING BASEDESIGNS USING CLIENT DATA,” and co-pending U.S. patent application Ser.No. 17/035,661, entitled “SYS IBMS AND METHODS FOR GUIDED SELECTION VIAVISUALIZATIONS,” each of which are incorporated herein by reference forall purposes.

BACKGROUND

The present disclosure is generally directed to techniques forgenerating base designs (e.g., motor control lineup) for an industrialautomation system. More specifically, the present disclosure relates totechniques for generating recommendations for a base design based oncustomer requirements and preferences.

This section is intended to introduce the reader to various aspects ofart that may be related to various aspects of the present techniques,which are described and/or claimed below. This discussion is believed tobe helpful in providing the reader with background information tofacilitate a better understanding of the various aspects of the presentdisclosure. Accordingly, it should be understood that these statementsare to be read in this light, and not as admissions of prior art.

Industrial systems may include various types of industrial deviceassemblies, such as motor control centers (MCCs), switchgear assemblies,and the like. Such industrial device assemblies are typically customordered from a manufacturer for a particular industrial site. Beforesubmitting a purchase order for a particular industrial device assembly,including design of a layout of a corresponding industrial deviceassembly, a customer may define specifications of the industrial deviceassembly and submit the specifications of the industrial device assemblythrough an approval cycle.

Defining the specifications may involve the customer selecting ordefining each parameter from a multitude of parameters (e.g., 10parameters, 100 parameters) related to the industrial device assemblybefore ordering the industrial device assembly from a manufacturer. Insome instances, because defining each specification and selecting everydesired preference manually involves detailed knowledge about theindustrial device assembly and the manufacturer, customers withouttechnical backgrounds or intimate knowledge of the industrial deviceassembly may not be able to efficiently define the specifications. Insome instances, the customer may not be aware of every availableparameter that is accepted or used by a manufacturer when producing theindustrial device assembly.

In addition to defining specifications, diagrams related to theindustrial device assembly (e.g., a single-line diagram, an elevationdrawing, an engineering document) may take time, as users using acomputer-aided design (CAD) program or some other suitable tool generatethe diagrams. That is, the user may receive customer data related to anelectrical power system and related industrial devices, such as anelectrical load list, and generate one or more diagrams representativeof the electrical power system. Upon completion, the one or morediagrams may be rendered on a display in an application executing on acomputer for viewing and review.

If the customer specifications, preferences, and/or customer data arechanged during or after design of the industrial device assembly or acorresponding diagram, the industrial device assembly or one or morediagrams may require a re-design to meet the updated specifications,preferences, and/or customer data.

The process of designing and re-designing the industrial device assemblyand/or the one or more diagrams can be arduous and time-consuming andmay often contribute to long delays on a particular project at anindustrial site. For example, the industrial device assembly may besubdivided into lineups, sections, units, or the like. Each lineup mayhave 1-N sections and each section may have 1-M units, whichrespectively contain at least one industrial automation device. Eachlineup, section, or unit may be re-designed to meet the updated customerspecifications which can lead to a significant delay at the industrialsite.

Furthermore, before the industrial device assembly can be designed,updated customer data may need to be obtained. Thus, a customer may bequeried multiple times to obtain the updated data. This may lead tofurther delays in the design process and may involve requesting datafrom the customer that is analyzed but not ultimately used.

SUMMARY

A summary of certain embodiments disclosed herein is set forth below. Itshould be understood that these aspects are presented merely to providethe reader with a brief summary of these certain embodiments and thatthese aspects are not intended to limit the scope of this disclosure.Indeed, this disclosure may encompass a variety of aspects that may notbe set forth below.

In one embodiment, a method for generating Ethernet modules based on abase design is provided. A processor may receive a selection of avisualization via a user input, wherein the visualization represents abase design for an industrial device assembly. Electrical load limitsmay be calculated for sections of the base design based dimensions ofthe sections, a quantity of the sections, a location of the industrialdevice assembly, and so forth. A number of Ethernet switch devices forthe sections based on the one or more electrical load limits may as wellas placements within the base design for Ethernet switch devices of thenumber of Ethernet switch devices may be determined. Further, theoperations may include presenting a layout of the industrial deviceassembly via a display. The layout is indicative of the number ofEthernet switch devices for the sections and the placements of theEthernet switch devices with respect to the base design.

In a further embodiment, a system for generating a base design isprovided. The system may include a processor, a memory storinginstructions that, when executed by the processor, cause the processorto perform operations. The operations may include receiving a selectionof a visualization via a user input, wherein the visualizationrepresents a base design for an industrial device assembly. Electricalload limits may be calculated for sections of the base design baseddimensions of the sections, a quantity of the sections, a location ofthe industrial device assembly, and so forth. A number of Ethernetswitch devices for the sections based on the one or more electrical loadlimits may as well as placements within the base design for Ethernetswitch devices of the number of Ethernet switch devices may bedetermined. Further, the operations may include presenting a layout ofthe industrial device assembly via a display. The layout is indicativeof the number of Ethernet switch devices for the sections and theplacements of the Ethernet switch devices with respect to the basedesign.

In an additional embodiment, a non-transitory computer-readable mediumstoring instructions are provided. When executed by a processor, theinstructions cause the processor to perform operations that includereceiving a selection of a visualization via a user input, wherein thevisualization represents a base design for an industrial deviceassembly. Electrical load limits may be calculated for sections of thebase design based dimensions of the sections, a quantity of thesections, a location of the industrial device assembly, and so forth. Anumber of Ethernet switch devices for the sections based on the one ormore electrical load limits may as well as placements within the basedesign for Ethernet switch devices of the number of Ethernet switchdevices may be determined. Further, the operations may includepresenting a layout of the industrial device assembly via a display. Thelayout is indicative of the number of Ethernet switch devices for thesections and the placements of the Ethernet switch devices with respectto the base design.

BRIEF DESCRIPTION OF THE DRAWINGS

These and other features, aspects, and advantages of the presentlydisclosed embodiments will become better understood when the followingdetailed description is read with reference to the accompanying drawingsin which like characters represent like parts throughout the drawings,wherein:

FIG. 1 illustrates a block diagram of a system for generating a motorcontrol lineup and corresponding single-line diagram, according to anembodiment;

FIG. 2 illustrates a flow chart of a process for generating a motorcontrol lineup, according to an embodiment;

FIG. 3 illustrates a graphical user interface for receiving client datarelated to the motor control lineup of FIG. 2, according to oneembodiment;

FIG. 4 illustrates a graphical user interface for selecting features ofthe motor control lineup of FIG. 3, according to one embodiment;

FIG. 5 illustrates a graphical user interface for determining a layoutof the motor control lineup of FIGS. 3 and 4, according to oneembodiment;

FIG. 6 illustrates a single-line diagram dynamically generated by thesystem shown in FIG. 1, according to one embodiment;

FIG. 7 illustrates a flow chart of a process for dynamically generatingthe single-line diagram shown in FIG. 6, according to one embodiment;

FIG. 8 illustrates a flow chart of a process for dynamically generatinga set of base designs and supporting modules based on the client data ofFIG. 3, according to one embodiment;

FIG. 9 illustrates a flow chart of a process for dynamically generatingsingle-line drawings, elevation drawings, and engineering documentsbased on a selected base design from the set of base designs generatedaccording to the process of FIG. 8, according to one embodiment;

FIG. 10 illustrates a graphical user interface for generating thesingle-line drawings, the elevation drawings, and the engineeringdocuments of FIG. 9, according to one embodiment;

FIG. 11 illustrates a graphical user interface that depicts informationrelated to the selected base design of FIG. 9, according to oneembodiment;

FIG. 12 illustrates a flow chart of a process for providing predefinedbase designs in response to the inability to generate the set of basedesigns of FIG. 8 based on the client data, according to one embodiment;

FIG. 13 illustrates a flow chart of a process for identifying Ethernetpower modules to incorporate into the selected base design of FIG. 9,according to one embodiment;

FIG. 14 illustrates a flow chart of a process for generating optionpacks associated with the selected base design of FIG. 9, according toone embodiment;

FIG. 15 illustrates a graphical user interface for allowing input of theclient data of FIG. 8, according to one embodiment;

FIG. 16 illustrates a graphical user interface that depicts a sliderfeature associated with the option packs of FIG. 14, according to oneembodiment;

FIG. 17 illustrates a graphical user interface that depicts parametersassociated with the option packs of FIG. 14, according to oneembodiment;

FIG. 18 illustrates a graphical user interface for selecting the optionpacks of FIG. 14, according to one embodiment; and

FIG. 19 illustrates a graphical user interface for swapping the selectedbase design of FIG. 9 with another base design, according to oneembodiment.

DETAILED DESCRIPTION

One or more specific embodiments will be described below. In an effortto provide a concise description of these embodiments, not all featuresof an actual implementation are described in the specification. Itshould be appreciated that in the development of any such actualimplementation, as in any engineering or design project, numerousimplementation-specific decisions must be made to achieve thedevelopers' specific goals, such as compliance with system-related andbusiness-related constraints, which may vary from one implementation toanother. Moreover, it should be appreciated that such a developmenteffort might be complex and time consuming, but would nevertheless be aroutine undertaking of design, fabrication, and manufacture for those ofordinary skill having the benefit of this disclosure.

When introducing elements of various embodiments of the presentdisclosure, the articles “a,” “an,” “the,” and “said” are intended tomean that there are one or more of the elements. The terms “comprising,”“including,” and “having” are intended to be inclusive and mean thatthere may be additional elements other than the listed elements. One ormore specific embodiments of the present embodiments described hereinwill be described below. In an effort to provide a concise descriptionof these embodiments, all features of an actual implementation may notbe described in the specification.

Industrial automation systems may be used in various contexts, such as amanufacturing plant, a resource extraction system, a hydrocarbonextraction site, a chemical refinery facility, an industrial plant, apower generation system, a mining system, a brewery, or the like. Forexample, in a resource extraction system context, a control system maycontrol load and position of a rod pump to perform an oil extractionprocess. Although examples are provided with regard to specificcontexts, one of ordinary skill in the art will recognize that theseexamples are not intended to be limiting and that the techniquesdescribed herein can be used with any suitable context.

Further, an electrical load list (e.g., motor load list) provideselectrical parameters for various electrical equipment of an electricalpower system (e.g., an industrial automation system), includinggenerators, switchgear, and electrical transformers. Based on theelectrical load list and other defined specifications (e.g., datarelated to desired industry and location of a customer), a base design(e.g., motor control lineup) may be generated. The base design specifiesattributes, model, components, lead time, catalog number, cost,description, name, related industry, and so forth associated with anindustrial device assembly. As used herein, the lead time may involvethe time between submitting a purchase order and completing productionof the industrial device assembly. In particular, a motor control lineupis an assembly of control devices for one or more motors of theelectrical power system that provide actuation and automation for asystem. The motor control lineup may include a motor control center(MCC) or inverters (e.g., drives) coupled to a common bus. The motorcontrol lineup may include motor starters, fuses or circuit breakers,and/or a power disconnect. A motor control lineup, which defines thecontrol devices therein and a layout for the control devices, may begenerated based on the electrical load list, data related to a desiredindustry, location of a customer, operations, and the like.

The data used to generate the base design (e.g., the motor controllineup) may be received from a customer via one or more questionnairesthat include numerous questions relating to specific preferences of, anddesired layouts of, the electrical system and the base design (e.g., themotor control lineup). However, the process of generating the basedesign (e.g., the motor control lineup) and layout may be time consumingand may involve requesting data from the organization that is analyzedbut not ultimately used.

The embodiments herein provide techniques to streamline the process forgenerating the base designs (e.g., the motor control lineup), desiredlayouts, and diagrams (e.g., single-line diagram, elevation drawings,editable engineering drawings) by reducing customer input. Rather thanhaving to complete numerous selections and questions, the customer mayprovide fewer inputs (e.g., 3 inputs, 5 inputs, 10 inputs) in thepresent embodiment and select a particular base design from a set ofbase designs generated by a computing system. By selecting theparticular base design, the customer bypasses having to define eachspecification and answering numerous questions related to an industrialdevice assembly to submit a purchase order for a particular industrialdevice assembly. Using an intelligent, knowledge-based algorithm, thecomputing system may provide, via a graphical user interface (GUI),various selectable base designs and option packs to the customer basedon customer inputs. As used herein, option packs represent additionalselectable functional groups (e.g., safety attributes, systemattributes, intelligence attributes, unit attributes) within each basedesign. The motor control lineup as used herein is an example of thebase design. Prior to discussing the base designs and correspondingoption packs in detail, generating the motor control lineup will bediscussed. As such, FIGS. 1-6 illustrate generating and displaying themotor control lineup and layout and a corresponding single-line diagram.

Generating Single-Line Diagrams for an Industrial System

FIG. 1 illustrates a block diagram of a system 100 for generating amotor control lineup and a corresponding single-line diagram based onreceived inputs, according to an embodiment. The system 100 includes aclient device 102, a monitor system 106, and a computing system 108,each connected to a network 104, for example, a wired local area network(LAN), a wireless local area network (WLAN), personal area network(PAN), wide area network (WAN), enterprise private network (EPN), theinternet, etc.

The client device 102 may be a personal computer, such as a desktopcomputer, a portable computer, such as a laptop or notebook computer, ora smart device, such as a tablet, smart phone, human-machine interface(HMI), or the like. In the present embodiment, the client device 102 isused by a customer to input data related to an electrical power system,including electrical equipment, customer preferences, and so forth.Further, the client device 102 may also be used to control and/or modifyoperations of the electrical power system. The client device 102transmits the input data to the computing system 108 via the network104. The input data may include an electrical load list, a geographiclocation of the customer or the industrial site where the electricalpower system will be installed, an industry of the customer or theelectrical power system, and customer preferences related to, forexample, safety and automation.

Examples of the industry input by the customer include “food andbeverage,” “oil and gas,” “automotive,” “marine,” “chemicals,” “cement,”“metals,” and the like. Examples of geographic locations provided by thecustomer include a hemisphere, a continent, a country, a state orprovince, a region within a country, and the like. The geographiclocation and industry associated with the customer may be obtained froma database, such as the database 110, which includes a user profile foreach of a plurality of organizations.

The user profile for a given organization may include the geographiclocation associated with the organization, one or more industries inwhich the organization operates, historical data related to motorcontrol lineups previously purchased by the organization, and otherrelated data, such as preferences for a layout of a motor controllineup. The historical data may include, for example, safety features,such as arc containment enclosures previously purchased by the customer.The historical data may also include particular layouts of motor controllineups previously purchased by the customer or other organizations.

The monitor system 106 may monitor input data provided by one or moreadditional organizations that have currently or previously submitteddata to the computing system 108. For example, the monitor system 106may monitor data related to a plurality of one or more existingelectrical systems that were designed using the computing system 108 ora similar device. The monitor system 106 may also monitor data relatedto one or more existing electrical systems that were not designed usingthe computing system 108 but that corresponding input data was receivedby the monitoring system or is stored in one or more databases 110. Thatis, some of the input data may be retrieved from one or more databases110 where data for a plurality of organizations is stored.

The computing system 108 includes an input/output (I/O) interface 112,an intake engine 114, a feature engine 116, a motor control engine 118(e.g., an MCC engine), a graphic engine 120, control circuitry 122, anda single-line engine 124. The computing system 108 also includes one ormore processors 126 and one or more memory devices 128. In someembodiments, each engine 114, 116, 118, 120, 122, 124 may have its ownprocessor 126 and/or memory device 128. In other embodiments, theengines 114, 116, 118, 120, 124 may share one or more processors 126and/or one or more memory devices 128. The one or more memory devices128 may include long-term and/or short-term storage and may be used forstoring data and/or program instructions (e.g., machine readable code,algorithms, etc.). The one or more processors 126 may be used to executethe program instructions stored on the one or more memory devices 128.Further, the one or more processors 126 may be configured to retrievedata from the one or more memory devices 128 and to store data (datagenerated from executing the program instructions, or data received fromother data sources) on the one or more memory devices 128.

The control circuitry 122 may be connected to one or more components ofthe computing system 108 (e.g., via a bus) and control operation of thecomponents of the computing system 108. For example, the controlcircuitry 122 may identify when input data is received from the clientdevice 102 and initiate an analysis of the input data by the intakeengine 114.

The I/O interface 112 may be connected to the network to receive andtransmit data, such as the input data. The intake engine 114 receivesthe input data from the I/O interface 112 and stores the input data inthe databases 110. The intake engine 114 analyzes the input data anddetermines whether additional information should be requested from thecustomer. For example, the intake engine 114 may determine whether alocation or industry has been provided by the customer. If not, theintake engine 114 may generate a request for this information to be sentto the customer.

A request for additional information may also be generated by the intakeengine 114 based on the input data. For example, if the input dataincludes a load list, information specific to a particular load orcorresponding motor, such as a voltage or current rating, may berequested form the user. The intake engine 114 may also receive inputdata from the monitor system 106 and store the data in one or moredatabases 110.

In some embodiments, load devices in the electrical load list may beused by the intake engine 114 to query existing designs of motor controllineups stored in the database 110 to determine suitable designs for therecommended motor control lineup. In this way, the load devices maydictate how the computing system 108 identifies suitable motor controllineup designs and the like.

The input data from the customer and the data in the database 110 may bein various formats. Thus, the intake engine 114 may include aprogrammatic interface that interprets and converts the data into aformat which can be used in determining the recommended motor controllineup.

The feature engine 116 analyzes the input data from the customer (e.g.,via the client device 102) and identifies features to be included in arecommended motor control lineup based on the input data. For example,the feature engine may identify an industry of the customer orcorresponding industrial automation project 130. Based on the industry,the feature engine 116 may analyze the input data from the one or moreadditional organizations stored in the database(s) 110 to identifycommon features purchased by other organizations in the same or similarindustry. The identified common features may be evaluated for possibleinclusion in the recommended motor control lineup.

Similarly, organizations in the same or similar industry have similarpreferences to satisfy local and/or national laws and/or guidelines.Thus, the feature engine 116 may also analyze the input data from theadditional organizations, or previous input data from the sameorganization, to identify parameters used in previous motor controllineup designs. Based on the parameters, the feature engine 116 mayidentify particular features of the motor control lineup that are commonto the customer, industry, and/or location of the industrial automationproject 130. For example, if the industry input by the customer is“commercial bottling,” the feature engine may identify motor controllineup features that are commonly requested or purchased by additionalorganizations in the “commercial bottling” industry based on the data inthe database(s) 110 related to the additional organizations.

Further, the geographic location of the customer or the industrialautomation project site may indicate certain parameters of theorganization. The geographic location may be indicative a utilityoperating voltage, emissions standards, requirements of the electricalsystem to comply with local laws and/or guidelines, etc. For example, anindustrial operating voltage (e.g., 110V or 240V), a control voltage(e.g., 12V or 24V) of the motor control lineup and the like. Similarly,the feature engine 116 may analyze data related to other organizationsin a geographic location or region similar to that of the customer orthe industrial automation project site. Thus, the feature engine 116analyzes the data from previous motor control lineup designs for eachorganization that is similar to the requesting customer to determineparticular features of the motor control lineup that may be common orsimilar to, for example, the industry and geographic location of therequesting customer.

The feature engine 116 may also identify particular features that arespecifically requested by the customer or satisfy one or morespecifications of the customer, including safety features and/orautomation features. For example, in the input data, the customer mayspecifically request arc containment. In such an embodiment, the featureengine 116 identifies the specified feature (i.e., arc containment) andincludes that feature in the motor control lineup. In some cases, thefeature engine 116 may determine that additional input is needed fromthe customer, such as specific safety features to be included in themotor control lineup. Example safety features may include arccontainment and withdrawable units. In some embodiments, the featureengine 116 may request the additional input from the customer.

In some embodiments, the feature engine 116 may include a machinelearning model (not shown), which may be trained using historical data.For example, the machine learning model may include historical customerdata from various industries and geographic locations. The machinelearning model may be updated each time a motor control lineuprecommendation is determined, or on some other schedule (after a setperiod of time has passed, after a set number of motor control lineuprecommendations have been generated, etc.). The updated machine learningmodel may be used by the feature engine 116 so that subsequent motorcontrol lineup recommendations take the most recent customer data intoaccount.

In some embodiments, the machine learning model may also analyze howvarious users interact with the recommended motor control lineup. Forexample, the recommended motor control lineup may be presented to a uservia a web browser executing on the client device 102. The machinelearning model may monitor how the customer interacts with therecommendation in the web browser to analyze any changes or selectionsthat are made and use these inputs as feedback for further training ofthe machine learning model. Monitoring and adding these interactions tothe machine learning model may enable the machine learning model tocontinually improve its ability to provide recommendations to users andto other organizations that share certain similarities with therespective organization.

The MCC engine 118 receives the features to be included in the motorcontrol lineup from the feature engine 116. The MCC engine 118identifies particular control devices (e.g., power disconnects, breakersor fuses, motor starters, interlock switches, etc.) and correspondingparameters (e.g., arc containment, withdrawable units, etc.) for therecommended motor control lineup that allow the features identified bythe feature engine 116 to work together. The MCC engine 118 may identifycontrol devices based on the input data from the customer as well ashistorical data from the customer or from similar customers stored inthe database(s) 110.

The MCC engine 118 may also determine a recommended layout of thecontrol devices of the motor control lineup. A size (e.g., an overallheight, an overall width, and an overall length) of the motor controllineup may be specified by a customer in the input data or may bedetermined based on the historical data. For example, the MCC engine 118identifies a size of each control device and determines one or morerecommended layouts of the control devices such that the control devicesfit within the size of the motor control lineup specified by thecustomer.

The graphic engine 120 generates a graphical representation of the oneor more recommended layouts of the motor control lineup to be renderedon a display of the client device 102. The graphical representation maybe formatted to be displayed in a web browser or native applicationexecuting on the client device 102. The graphical representation mayinclude each of the control devices identified by the MCC engine 118. Insome embodiments, the graphical representation may be an elevation viewof the motor control lineup.

The single-line engine 124 may generate a single-line diagramrepresenting the motor control lineup. The single-line diagram may be avisual representation of the electrical system(s) of the industrialautomation project 130. The electrical system may be complex and thesingle-line diagram provides a simplified visual representation of theelectrical system in two-dimensions. To generate the single-linediagram, the single-line engine 124 may generate a graphical object foreach of the electrical equipment in the electrical load list and each ofthe control devices in the motor control lineup. The graphical objectsmay be generated using scalable vector graphics, as discussed in moredetail below.

If the input data is updated or modified by the customer, the computingsystem 108 may dynamically update the recommended motor control lineupand corresponding features, the layout of the motor control lineup, thegraphical representation of the layout of the motor control lineup, andthe single-line diagram based on the updates/modifications provided bythe user. For example, if a new load is added to the electrical loadlist, the MCC engine 118 may determine that a new control device is tobe added to the motor control lineup. The MCC engine 118 may alsodetermine that one or more parameters (e.g., a voltage or currentcapacity) of one or more of the control devices is to be updated basedon the new load. The graphic engine 120 may dynamically update thegraphical representation of the motor control lineup to include the newor updated control device. The single-line engine 124 may also generatea new or updated graphical object to be included in the single-linediagram.

FIG. 2 illustrates a flow chart 150 of a process for generating arecommended motor control lineup based on inputs provided by a customer.The flow chart 150 begins at operation 152 where input data associatedwith a first client (i.e., the customer) is received. The input data maybe obtained directly from the first client (e.g., input via a graphicaluser interface) or from a database. That is, the input data mayrepresent near real-time (e.g., current as of seconds, minutes, hours,days, etc.) specifications and preferences of the first client.

At operation 154, historical data associated with the customerrequesting the design, or a plurality of other customers is obtained.The historical data may be obtained from a database, directly from thecustomer requesting the design, or directly from one or more of theplurality of other customers. For example, the historical data may beobtained from the database(s) 110 or directly from the monitor system106 discussed with respect to FIG. 1.

At operation 156, the input data and the historical data are analyzed toidentify one or more associations between the input data and thehistorical data. The one or more associations between the input data andthe historical data may be similarities between the input data andhistorical data. For example, a same or similar geographic location,industry, and/or product/process may be identified between the firstclient and one or more previous designs for the customer or theplurality of other customers. In such an embodiment, the one or more ofthe plurality of other customers may be associated with the firstclient.

If the geographic location of a project provided by the first client isa region within a country, the corresponding country may be the same orsimilar to that of one or more previous projects from the same customeror the plurality of other customers. That is, the intake engine 114,discussed with respect to FIG. 1, may identify a broader geographicregion or country than that provided by the first client. Thus, thenumber of previous projects having a same or similar geographic locationmay be increased to widen the scope for possible matches and give abetter recommendation for the motor control lineup.

At operation 158, one or more features of the recommended motor controllineups are determined based on the input data and the historical data.Some of the features may be common across each of the one or morerecommended motor control lineups. For example, each recommended lineupmay include four motor starters and four disconnects. The recommendedlineups may differ in features related to safety, such as arccontainment, and intelligence, such as remote monitoring and access forremote control and remote reset of control devices.

The features determined at operation 158 may also include variouselectrical parameters of the motor control lineup including a busvoltage, a frequency, a control voltage, an operating electrical load,and a maximum electrical load. The electrical parameters may bedetermined based on the input data and the historical data. For example,a bus voltage for the motor control lineup may be determined based onthe geographic location provided in the input data and bus voltages ofmotor control lineups in the same or similar geographic locations foundin the historical data.

At operation 160, a projected cost of the recommended motor controllineup is determined. The cost may take into account the variouselectrical parameters, the control devices, safety features, and anyother specifications or parameters requested by the customer. Forexample, price data for each component and/or service may be stored(e.g., in the database), or retrieved and then summed according to therecommended motor control lineup to determine the projected cost of thesystem. The projected cost may be provided to the customer in one ormore currencies.

At operation 162, the computing system 108 discussed with respect toFIG. 1 may generate one or more graphical objects representing featuresof the recommended motor control lineups. The recommended motor controllineups may be rendered as a summary or as a list of features includedin each lineup via a display of the client device. Some features may becommon to each recommended motor control lineup, such as arccontainment, while other features may differ between the recommendedlineups, such as intelligence options. The recommended motor controllineups are rendered on the display to be presented to the customer. Insome embodiments, the recommended motor control lineups may be presentedto the customer as elevation views. For example, an elevation view maybe a visual representation of a front face of the recommended motorcontrol lineup, as depicted within the graphical user interfaceillustrated in FIG. 5. If the customer selects (e.g., clicks on) one ofthe recommended motor control lineups, the computing system may thenpresent an elevation view of the selected motor control lineup to thecustomer, as discussed in more detail below.

At operation 164, the computing system receives a selection of one ofthe recommended motor control lineups. For example, if the recommendedmotor control lineups are presented to the customer in a web browser,the computing system may receive a selection of one of the lineups whenthe customer clicks on that lineup.

At operation 166, the computing system determines a layout of theselected motor control lineup. The layout may include a position of eachcontrol device within the physical motor control lineup. The physicalmotor control lineup may include one or more vertical sections. Each ofthe one or more vertical sections may include one or more of the controldevices. Each section of the selected lineup may include various controldevices having a common power. Thus, the computing system may identify apower common to one or more of the control devices of the selectedlineup. For example, one section of the selected motor control lineupmay include control devices with a common control voltage of about 24volts. Another section of the selected lineup may include controldevices having a common control voltage of about 12 volts. As anotherexample, one section of the selected motor control lineup may includevarious control devices having a common bus voltage of about 220 volts.

At operation 168, the computing system generates a visual representationof the layout of the selected motor control lineup. To do so, thecomputing system may generate one or more graphical objects for eachsection of the selected motor control lineup. In some embodiments, thecomputing system may generate a graphical object for each controldevice. Upon display to the user, the user may provide inputs thatmodify the proposed layout.

At operation 170, the computing system determines if an input to modifythe layout of the selected motor control lineup has been received. Ifso, the computing system modifies the layout of the motor control lineupbased on the received input at operation 172. The computing system thenupdates the visual representation of the modified layout at operation168.

If no input to modify the layout is received and/or the user providesaffirmative approval of the proposed layout, the computing systemrenders the visual representation of the selected motor control lineupat operation 174. The visual representation may be rendered at theclient device via a web browser or native application executing thereon.

Once rendered, the computing system may continue to monitor foradditional input indicating a modification to the MCC layout. If anadditional input is received, the layout of the lineup may be modifiedat operation 172 and the visual representation may be updated based onthe additional input at operation 168. The modified visualrepresentation may be rendered at operation 174.

FIG. 3 illustrates a graphical user interface (GUI) 175 for receivinginputs of client data. The GUI 175 may be presented to a customer via aclient device, such as the client device 102 discussed with respect toFIG. 1. The GUI 175 may be presented to the customer via a web browseror a native application executing on the client device. As illustrated,the GUI 175 includes a first input portion 180, which includes a numberof fields for customer or project specific data. A second input portion208 is provided for receiving inputs defining an electrical load list.

The first input portion 180 includes data fields for a location 182 ofthe customer or the industrial automation project 130 and an industry184 of the customer or the industrial automation project 130. The firstinput portion 180 also includes data fields for electrical powerrequirements of the customer or the industrial automation projectincluding a line voltage 192, a frequency 194, an enclosure type 196, asimultaneous load 198, a control voltage 200, a future expansion 202, ahorizontal bus rating 204, and an estimated bus size 206.

As shown, one or more data fields on the GUI 175 may include an asterisk(*) 222. The asterisk 222 may indicate a “required” data field which isa minimum required data for the computing system to generate arecommended motor control lineup. Data fields that do not include theasterisk 222 may be optional data fields to be completed by the customerwhich may improve an accuracy of the computing system to provide arelevant recommendation of a motor control lineup. For example, the linevoltage 192 may be input by the customer if known to indicate a voltageof the area or region where the industrial automation project site, andthus the motor control lineup, is or will be located. Similarly, thefrequency 194 may indicate a line frequency in the area or region wherethe motor control lineup will be installed. Data fields that do notinclude the asterisk 222 may be obtained by the computing system fromthe electrical load list.

The enclosure type 196 may indicate a minimum enclosure rating for thevarious control devices in the motor control lineup. The enclosure type196 may be a customer preference or may be a requirement of a local lawor standard for the location or the industry of the industrialautomation project 130. The simultaneous load 198 may indicate apercentage of the loads in the load list provided in the second datainput portion 208 which may be active at any given time during operationof the motor control lineup.

The control voltage 200 may be a range or average of the controlvoltages for all control devices in the motor control lineup. Thecontrol voltage 200 may also be a maximum control voltage for the motorcontrol lineup. The future expansion 202 may indicate a percentage ofthe motor control lineup that is to be reserved for potential futureexpansion for the industrial automation project 130. For example, thefuture expansion 202 field may indicate a percentage of the volume(e.g., space) of the motor control lineup that is to be left empty forcontrol devices to be added in the future. That is, the customer mayestimate a number of control devices to be added to the motor controllineup in the future and reserve a percentage of the motor controllineup for that purpose.

As should be understood that the data fields shown in the GUI 175 aremerely examples and many other data types of data may be requested to beinput by the customer. Further, data input into the data fields of thefirst input portion 180, such as the line voltage 192, the frequency194, the horizontal bus rating 204, and the estimated bus size 206 maybe used by the computing system as baseline values. However, thecomputing system may determine that a different value is needed forthese data fields based on the electrical load list.

The second input portion 208 for the electrical load list may include alist of all expected electrical loads in the industrial automationproject 130. That is, the load list is a collection of all expectedloads to be connected to one or more power supplies, such as generators.The second input portion 208 may include one or more columnsrepresenting various electrical parameters of each load. As illustrated,the electrical load list in the second input portion 208 includes a lineitem number 210 for each load. Data for each load may include a power212, a full load amp (i.e., electrical current) rating 214, a type orapplication 216 of the load, and a corresponding motor name 218.

It should be understood that the electrical load list may include anynumber of electrical parameters specific to all or some of theelectrical loads. For example, the electrical load list may includeelectrical parameters for each load such as a nominal rating, a powerfactor, an efficiency, a consumed load, a load factor, and the like. Itshould also be noted that the layout of GUI may be changed withoutchanging a scope or function of the embodiments described herein. Forexample, a position of the first input portion 180 the second inputportion 208 may be interchanged, or otherwise positioned differentlythan shown in FIG. 3.

FIG. 4 illustrates the graphical user interface 175 depicting a screenfor receiving selection of features of a motor control lineup. As shown,the first input portion 180 is similar to that illustrated in FIG. 3.However, a third input portion 230 depicts one or more recommended motorcontrol lineups 232, 242, 244. Each recommended motor control lineup232, 242, 244 may include a title 234, a list of one or more features236, and an estimated cost 238. The title 234 and the list of features236 may be generated by the computing system based on the input dataprovided by the customer.

The list of features 236 may be common to each recommended motor controllineup 232, 242, 244, facilitating ease of comparison between therecommended motor control lineups 232, 242, 244. Each individual featureof the list of features 236 may be identified as included or notincluded in a particular recommended motor control lineup by a visualobject presented in the GUI 175. For example, the feature of intelligentsoftware is not included in the recommended motor control lineups 232and 244, as indicated by an ‘X’ next to the intelligent softwarefeature. However, the intelligent software is included in therecommended motor control lineup 242 as indicated by a checkmark next tothe intelligent software feature. Some features 236 of the list may becommon to each recommended motor control lineup 232, 242, 244. Forexample, each recommended motor control lineup 232, 242, 244 includes apower monitor and an insulated bus, as indicated by the checkmarks shownin each recommended motor control lineup 232, 242, 244.

In some embodiments, each recommended motor control lineup 232, 242, 244includes a safety indicator and an intelligence indicator. The safetyand intelligence indicators provide a fast and efficient visualcomparison for each recommended motor control lineup. As shown, thesafety and intelligence indicators of the recommended motor controllineup 242 indicate an increased intelligence level while the safety andintelligence indicators of the recommended motor control lineup 244indicate an increased safety level, in accordance with the titles 234.

Each recommended motor control lineup 232, 242, 244 also includes avisual object that the customer can click on or otherwise choose toindicate a preference of the respective motor control lineup 232, 242,244. As shown, each motor control lineup 232, 242, 244 includes a“Select” visual object that can be selected by the customer.

In some embodiments, the customer may interact with the third inputportion 230 to select one or more features in the list of features 236that are indicated as not included in a particular recommended motorcontrol lineup. For example, the customer may be able to select a“Safety Rating” feature in the recommended motor control lineup 242. Thefeature may be selected by clicking on the feature or the correspondinginclusion indicator (e.g., the check mark or ‘X’).

Based on this user input, the system may check to determine whetherthere is an existing motor control lineup having the specifiedcombination of features, and if not, attempt to create a custom motorcontrol lineup having the specified combination of features. The systemmay then update the third input portion 230 based on the user feedbackto include the motor control lineup having the specified combination offeatures. In some embodiments, all of the motor control lineup optionsin the third input portion 230 of the GUI 175 may be updated based onthe user feedback. For example, the third input portion 230 of the GUI175 may update to display a selection of motor control lineup optionsthat all include and/or omit the features toggled by the user accordingto the user's inputs.

FIG. 5 illustrates the GUI 175 for reviewing a proposed layout of anMCC, according to one embodiment. Once the customer chooses features forthe motor control lineup as discussed above, the computing system maygenerate a graphical representation of the chosen lineup and render thatrepresentation in a fourth portion 254 of the GUI 175. A fifth portion250 of the GUI 175 may include general information regarding the motorcontrol lineup and a corresponding industrial automation project 130. Asixth portion 252 of the GUI 175 may include a nested orcollapsible/expandable line item view of the motor control lineup.

As shown, the graphical representation of the chosen motor controllineup depicted as a motor control center (MCC) lineup may be anelevation view 256. The elevation view 256 may include one or moresections or columns of the motor control lineup. The sections of themotor control lineup may be a visual representation of how the motorcontrol lineup will be shipped to the customer or to the industrialautomation project site. The elevation view 256 may include a blockrepresenting at least each control device included in the electricalload list, discussed above.

The elevation view 256 may be interactive such that the customer canclick on and drag the individual blocks of the motor control lineup todifferent locations within the corresponding column or a differentcolumn. For example, the customer may click on the second block in“Column 3.” When a block is selected, that block may be highlighted, asshown. A corresponding line item in the collapsible line item view inthe sixth portion 252 may also be highlighted, as shown. Further, aninformation block 264 may be rendered in the GUI 175 showing specificdata related to the selected block.

Once the block is selected, the customer may be able to drag theselected block higher or lower in “Column 3” of the elevation view 256or to a location in a different column. Once the block is moved, thecomputing system may re-determine a layout of the motor control lineupand render an updated elevation view 256 including the changes. Forexample, if the selected block is moved to a column having blocks ofsizes different than a size of the selected block, one or more otherblocks may be moved fill the vacant space left by the selected block aswell as ensure sufficient space in the column with the new location ofthe selected block.

The GUI 175 may also include various functional buttons that can be usedduring design of the motor control lineup or after a final layout isdetermined. For example, a first button 258 may be used to save anychanges made to the motor control lineup. A second button 260 maygenerate and submit a request for proposal to the manufacturer of themotor control lineup. A third button 262 may generate one or moredocuments related to the motor control lineup. For example, thedocuments related to the motor control lineup may include a request forproposal, a request for quotation, a corresponding single-line diagram,a formal elevation view, and the like. Each of the one or more documentsmay be generated in any format, including a text document, a portabledocument format (PDF), an image, or the like.

FIG. 6 illustrates a single-line diagram 270 generated by the system anddisplayed in the graphical user interface 175, according to oneembodiment. The single-line diagram 270 provides a visual representationof the electrical systems of the industrial automation project 130,including the control devices of the motor control lineup. Thesingle-line diagram 270 may be dynamically generated by the computingsystem at any time during the MCC recommendation process describedherein. For example, the single-line diagram may be generated when thecustomer inputs data including an electrical load list into the GUI 175,as discussed above. As any changes are made to the input data orpreferences of the customer, the computing system may update thesingle-line diagram to reflect those changes. Thus, the single-linediagram is a visual representation of the motor control lineup asmodified by the customer.

Single-line diagrams are typically manually generated by a user using acomputer-aided design (CAD) program or some other suitable tool. Thatis, the user may receive information related to an electrical powersystem, such as an electrical load list and generate a single-linediagram representative of the electrical power system. This process togenerate a single-line diagram may be resource intensive and timeconsuming. Further, any changes or corrections made to the single-linediagram adds to the process and increases the amount of time used togenerate the diagram. Thus, the embodiments described herein providetechniques to dynamically generate a single-line diagram for viewing inreal-time during a design phase of an industrial automation project asthe electrical load items or customer preferences are changed or addedto the design in real-time. The single-line diagram may be dynamicallymodified while the electrical load list is generated, modified, or thelike.

To generate the single-line diagram 270, the computing system mayreceive an input representative of one or more electrical componentsfrom the load list. The load list may be fully or partially completed.As the computing system receives each input of the load list, thecomputing system may identify a graphical object representative of acorresponding component in the load list. Before generating thegraphical objects, the computing system may identify a web browser orapplication used by the customer. The computing system may generate thegraphical objects in a format that is compatible with the web browser ornative application employed by the customer.

After a particular the graphical object is generated, the computingsystem may dynamically add that graphical object to a single-linediagram presented via the web browser or native application used by thecustomer. Thus, the single-line diagram presents a real-time visualrepresentation of the electrical equipment that are part of the loadlist at any given time. Further, as changes are made to the electricalload list, the computing system may dynamically update the graphicalobjects, such that the single-line diagram is updated to reflect thechanges as the changes are made. That is, the computing systemdynamically generates and updates the single-line diagram to reflect acurrent state of the electrical load list.

Connections between the graphical objects of the single-line diagram maybe generated while the graphical objects corresponding to the componentsof the load list are generated. In some embodiments, the connections maybe generated after all current graphical objects are generated andrendered in the single-line diagram. Thus, in some embodiments,generating and rendering the connections between components of thesingle-line diagram may be performed concurrently with generating andrendering the graphical objects representing the components of the loadlist. In other embodiments, generating and rendering the connections maybe performed as separate operations from generating and rendering thegraphical objects corresponding to the components of the load list,respectively. The connections between components may be generated aspart of the graphical objects representing the component of the loadlist or as additional graphical objects.

In some embodiments, the load list is generated by the customer directlyon the server using a web-based application. In that case, the computingsystem may continually analyze the load list and generate a graphicsobject for each electrical component thereof. As the graphics objectsare generated, the computing system may update the single-line diagrampresented on the display. That is, as additional pieces of electricalequipment are added to the load list, the single-line diagram is updatedby the computing system. Thus, a current view of the single-line diagramin the web browser or application corresponds to the current electricalload list.

Moreover, the current view of the single-line diagram may be distributedto a number of computing systems communicatively coupled to thecomputing system receiving the input. With this in mind, in someembodiments, the customer may provide the load list remotely via anetwork to supervisors, subordinates, clients, customers, vendors,suppliers, contractors, etc. As such, a server computing system mayreceive and analyze the load list to identify various electricalequipment that are part of the load list. The server computing systemmay generate a graphical object for each electrical equipment in theload list.

In some embodiments, the server computing system may generate thegraphical objects as scalable vector graphics (SVG). In otherembodiments, the format of the graphical objects (and the single-linediagram) is a format other than SVG, such as encapsulated postscript(EPS), portable document format (PDF), or raster graphics. In any case,the server computing system or any other suitable computing system maydynamically convert the input data representative of the load list itemsinto graphical objects interpretable by the computing system intended toreceive the single-line diagram visualization.

In some embodiments, the server computing system may convert the inputdata from JSON data to SVG data as the input data is received, such thatthe server computing system may send the SVG data to the computingdevice, which may generate the single-line diagram visualization basedon the SVG data. In some embodiments, the input data, the single-linediagram, or the graphical object data may also be used to generate anelevation view that represents how components that are part of thesingle-line diagram may be positioned within an enclosure or acollection of enclosures.

FIG. 7 illustrates a flow chart 280 of a process for dynamicallygenerating a single-line diagram, according to one embodiment. The flowchart 280 begins at operation 282 where input data is received (e.g.,via the GUI). The input data may include an electrical load list and anyother relevant customer data including preferences or specifications.The electrical load list may include, for example, generators, motors,corresponding control devices, and the like. The input data may beprovided by the customer via a graphical user interface (GUI) such asthat described above with respect to FIGS. 3-5.

At operation 284, the computing system generates a graphical objectrepresentative of each item in the electrical load list. The graphicalobject may be generated by applying a set of rules to the items in theelectrical load list. For example, the computing system may generate ascalable vector graphics (SVG) object for each item in the load list ata current time. The computing system may determine a layout of the SVGobjects based on the input data in the electrical load list and therecommend motor control lineup. For example, the computing system maydetermine what SVG objects of the single-line diagram are to beconnected to each other and in what order along a given load line. Thecomputing system may utilize historical data from the customer or theadditional customers to determine connections between the SVG objectsand an order of the SVG objects in the single-line diagram.

Once the single-line diagram is generated, the graphical objects may bestored in one or more databases, such as the databases 110 discussedwith respect to FIG. 1. Further, the graphical objects and thesingle-line diagram may be stored and used to train a machine learningmodel. For example, the machine learning model may include historicalsingle-line diagrams (including corrections or changes made to thesingle-line diagram by an associated customer) and corresponding motorcontrol lineups to ensure the most recent customer data is taken intoaccount. Further, the machine learning model may improve an accuracy ofthe single-line diagram by using the most recent customer data.

At operation 286, the computing system determines if updated input datahas been received. For example, the computing system may identify amodification to the previously received input data or new input data.

If updated input data is received, the computing system may modify oneor more of the scalable vector graphics objects or generate one or morenew scalable vector graphics objects as needed, at operation 288. If thecomputing system does not detect updated input data, the scalable vectorgraphics representation of the electrical load list is rendered to bepresented to the customer at operation 290. That is, the computingsystem renders each scalable vector graphics object in the form of thesingle-line diagram.

In summary, one or more recommended motor control lineups and asingle-line diagram may be dynamically generated from an electrical loadlist. Regarding the recommended motor control lineup, the computingsystem analyzes organization data related to the organization associatedwith a user and other organizations with similar attributes, such asindustry and geographic location. The organization data may be receivedvia a web browser or retrieved from a database. The recommended motorcontrol lineup is presented to the customer via a GUI (displayed in anative application or a web browser) in an elevation view where the usercan modify the lineup as desired.

The single-line diagram may provide a visual representation of the motorcontrol lineup and can be generated from the motor control lineup, asmodified by the user. After the electrical load list is received, agraphics engine identifies each electrical component in the load listand generates a corresponding graphical object. As each graphical objectis generated, the graphics engine updates the single-line diagram, whichis concurrently rendered in the web browser. Advantageously, embodimentsdescribed herein provide a real-time rendering of the single-linediagram which is updated throughout a lifecycle of a project. Further,embodiments described herein improve an efficiency of generating asingle-line diagram because individual graphical objects can be updatedwithout having to manually revise the single-line diagram.

The techniques disclosed herein improves accuracy of the motor controllineup recommended to the user by integrating data into the analysiswhich may not be directly related to the customer. Further, techniquesdescribed herein reduce an amount of computing resources needed togenerate the recommended motor control lineup. Embodiments describedherein also provide a real-time rendering of the single-line diagramwhich is updated throughout a lifecycle of a project. Further,embodiments described herein improve an efficiency of generating asingle-line diagram because individual graphical objects can be updatedwithout having to manually revise the single-line diagram.

Advantageously, embodiments disclosed herein provide techniques toreduce a time required to design, re-design, and prepare an order forindustrial device assemblies and a corresponding single-line diagram.Thus, the embodiments disclosed herein reduce project delays and providea streamlined process for the design and ordering process of industrialdevice assemblies.

Generating Base Designs and Layouts for Each Electrical Load List andCorresponding Client Data

As mentioned above, the motor control lineup is an example of a basedesign generated based on the electrical load list and client data(e.g., industry data, location data). The base design may be a list ofelectrical components designated in a hierarchical fashion, such thatthe electrical components (e.g., industrial equipment, networkequipment), mechanical components, and the like are used in coordinationwith each other to perform industrial automation operations. While themotor control lineup may define the control devices for one or moremotors of an electrical power system and a layout for the controldevices, the base design in general may define attributes, model ofelectrical components (e.g., the control devices), type of electricalcomponents, lead time (e.g., time between submitting a purchase orderand completing production of the industrial device assembly), catalognumbers, costs, descriptions, names, related industries, and so forthassociated with an industrial device assembly.

The embodiments herein provide techniques to streamline the process forgenerating base designs (e.g., motor control lineups), desired layouts,and diagrams (e.g., single-line diagram, elevation drawings, editableengineering drawings) by reducing an amount of customer input used togenerate a suitable layout and a collection of devices to use. Thedesired layouts may include a desired position of each electricalcomponent (e.g., control devices) within the physical industrial deviceassembly. For example, the industrial device assembly may be subdividedinto lineups, sections, columns, units, modules, or the like. Eachlineup may have 1-N sections and each section may have 1-M units, whichrespectively contain at least one industrial automation device orcontrol device. For example, a desired layout for an example industrialdevice assembly may include 10 sections each with 20 units, therebysupporting a total of 200 units. The number of industrial automationdevices that may be placed within each unit may be dependent onelectrical load limits of respective sections and units. Positioning ofthe industrial automation devices within the physical industrial deviceassembly may be limited based on physical dimensions of sections andunits within the industrial device assembly, electrical connectivity,and other electrical load limits. For example, with respect toelectrical connectivity, if a unit includes 1 electrical port that canconnect to 5 devices, the unit may include no more than 5 industrialautomation devices.

As mentioned previously, in order to submit a purchase order to amanufacturer for a particular industrial device assembly, a customer maydefine numerous specifications and complete questions to generate basedesigns, layouts, and diagrams, which are used to submit the purchaseorder. Because defining each specification and selecting every desiredpreference manually involves detailed knowledge about the industrialdevice assembly and the manufacturer, customers without technicalbackgrounds or intimate knowledge of the industrial device assembly maynot be able to efficiently define specifications. In some instances, thecustomer may not be aware of every available parameter or specificationthat is accepted or used by a manufacturer when producing the industrialdevice assembly. For example, a manufacturer may provide safetyattributes (e.g., arc containment) when producing particular industrialdevice assemblies. A customer without technical background or withoutintimate knowledge of the manufacturer and the industrial deviceassembly may inadvertently neglect the opportunity to select parametersrelated to such safety attributes. Further, manually selecting eachparameter or specification may be time-consuming, expensive, andinefficient.

Rather than having to complete numerous selections and questions tosubmit a purchase order, the embodiments described herein may allowcustomer may provide a certain number of inputs (e.g., 3 inputs, 5inputs, 10 inputs), such that a system may generate an appropriatedesign and layout suitable for the customer's purposes. For example, thecustomer may submit an electrical load list, industry data, and locationdata as inputs to a graphical user interface (GUI) of a computingsystem. As discussed above, the location data may include a geographiclocation of the customer or an industrial site where the industrialdevice assembly will be installed, while the industry data may includean industry of the customer or the industrial device assembly. Based onsuch customer inputs, the computing system may determine numerousparameters (e.g., 100 parameters, 200 parameters) related to a number oflevels of operations for various components of the industrial deviceassembly to generate customer-specific base designs. The parameters mayinclude safety attributes (e.g., arc containment), intelligenceattributes (e.g., processing power), system attributes (e.g., controlvoltage), communication attributes (e.g., available number of ports),unit attributes (e.g., withdrawable units), and the like related to theindustrial device assembly.

The parameters may define one or more levels of operations for each ofelectrical component of the industrial device assembly based on theclient data For example, the safety attributes may define a level ofprotection or an amount of protective features (e.g., voltage isolation,maximum current, clearance distances), protective mechanical feature(e.g., shield, type of wiring), or other design feature that may enhancesafety attributes related to using the industrial device assembly orequipment within the industrial device assembly.

The intelligence attributes may include types of devices and/orcontrollers that may be used by one or more components of the industrialdevice assembly that may control the operations of the components or theindustrial device assembly. That is, the intelligence attributes maydetail the processing power or capabilities of respective components,the abilities of the respective components to autonomously performcertain processes or tasks, the capabilities for the respectivecomponents to send commands to other devices, and the like.

The communication attributes may include parameters or settings thatdescribe the communication capabilities of the respective component orindustrial device assembly. As such, the communication attributes mayinclude a type of communication protocol that the respective componentuses, a number of communication ports available for the respectivecomponent, or the like.

The unit attributes may include parameters that describe the physicaldimensions (e.g., length, width, height, weight) of each of therespective components of the industrial device assembly. As mentionedabove, the industrial device assembly may be subdivided into 1-Nsections, and each section may have 1-M units, which respectivelycontain at least one electrical component or control device. Eachsection and corresponding unit may have electrical load limits andparticular dimensions that help define the maximum size (e.g., length,width, and height) and maximum weight of each of the respectivecomponents disposed within each section and corresponding unit.

Using a machine-based processing and algorithms and a database ofhistorical data related to client information, client preferences, andprevious industrial device assemblies, the computing system may identifythe parameters and subsequently identify a set of base designs andcorresponding supporting modules based on the identified parameters. Forexample, supporting modules and the base design may be identified basedon customer preferences such as for a particular type of drive product.That is, the particular type of drive product may dictate a selection ofa particular base design. The supporting modules may include additionalcomponents that may not have been a part of the electrical load list butmay be useful in enabling certain components to operate or allow theindustrial device assembly to perform efficiently. The supportingmodules may assist the operation of at least one the electricalcomponents within the industrial device assembly or base design. Forexample, a supporting module may include a fan to a cool a unit withinthe industrial device assembly. While the fan does not control a motorof the industrial device assembly (e.g., MCC), the fan maintains a safeoperating environment for the electrical components. Further, supportingmodules may include mechanical stands that allow certain devices to havea certain amount of clearance from a floor, power supply modules thatensure that a sufficient amount of regulated voltage is provided to acomponent, and the like. Additional examples of the supporting modulesmay include main switches, Ethernet switches, power supplies, Ethernetpower supplies. As used herein, main switches may refer to switchingdevices such as a primary circuit breaker that provides power to theentire industrial device assembly and downstream devices. As such, themain switches protect the MCC from over current faults and controlproviding power to the MCC. Using machine-learning algorithms or othersuitable algorithms that account for the load list, geographic locationof the client, and/or historical data associated with the client, theprocessor 126 may select a type and size of one or more main switchesand corresponding power structures to support the entire MCC and otherconnected components. In turn, the computing system may display the setof base designs to the client.

After reviewing the set of base designs, the client may select aparticular base design. By selecting the particular base design, thecustomer may bypass defining each parameter and completing numerousquestions related to an industrial device assembly to submit a purchaseorder for a particular industrial device assembly. Based on the selectedbase design, the processor 126 may generate and display a layout, whichis a graphical representation indicative of the positioning of eachelectrical component within the industrial device assembly.

With the foregoing in mind, FIG. 8 is a flowchart of process 300 fordynamically generating base designs and corresponding supporting modulesfor a particular industrial system based on client data. As mentionedabove, the base designs are generated using the electrical load list andclient data (e.g., industry data, location data). Each base design mayinclude a list of electrical components designated in a hierarchicalfashion, such that the electrical components are used in coordinationwith each other to perform industrial automation operations. As such,the base design may provide a framework for different electricalcomponents to physically and communicatively interconnect with eachother. The process 300 may be performed by any suitable system that mayreceive client data via a GUI and instruct a processor to identifyparameters to generate base designs and corresponding supportingmodules. While the process 300 is described using steps in a specificsequence, it should be understood that the present disclosurecontemplates that the described steps may be performed in differentsequences than the sequence illustrated, and certain described steps maybe skipped or not performed altogether. In some embodiments, the process300 may be implemented by executing instructions stored in a tangible,non-transitory, computer-readable medium, such as the memory device 128,using a processor, such as the processor 126.

According to the process 300, the processor 126 receives client datafrom a user via the GUI (block 302). The client data may include anelectrical load list (e.g., upload a spreadsheet indicative of theelectrical load list via the GUI), a geographical location associatedwith the user or installing an industrial device assembly, and anindustry related to the industrial device assembly. The client data maybe specified by the user via the GUI or some other suitable inputcomponent. In some embodiments, the user may submit the electrical loadlist while the processor 126 may automatically determines thegeographical location and the industry of the client based on historicaldata associated with the client related to previous industry deviceassemblies. Such historical data for each client and correspondingprevious industry device assemblies may be stored in a database or adevice library that is accessible by the processor. The database ordevice library may include information related to the client data,parameters, base designs, supporting modules, layouts, single-linedrawings, elevation drawings, engineering proposal documents, and thelike for each client for particular industry device assemblies.

The geographical location may also be determined based on sensor dataindicative of the client's location, a location of an existingindustrial system associated with the client, or the like. As such, thesensor may be any suitable location sensor, such as a global positioningsensor (GPS) or the like.

After determining the geographical location and the industry of theclient, the processor 126 may display the determined geographicallocation and the industry to the client via the GUI. In turn, the usermay verify or change the geographical location and the industry.Further, the user may be able to modify the electrical load list withone or more modified electrical components after submission of theclient data and even after generation of the base designs. For example,after the base designs and corresponding modules have already beengenerated, the user may wish to change an electrical componentidentified based on the client data. Thus, the user may submit amodification to the electrical component or submit another electricalload list with the modification to the electrical component. The usermay not have to re-submit each of the previous inputs as previouslysubmitted inputs may be saved by the processor 126 and used toregenerate the base design and corresponding supporting modules based onthe modification to the electrical component. As such, the process 300may provide an efficient and convenient way for the user to dynamicallymodify inputs or add new inputs while generating a layout for theindustrial system.

After the client data has been received, the processor 126 may determineadditional parameters associated with electrical components of theindustrial device assembly (block 304). In some cases, the user mayselect numerous parameters (e.g., 100 parameters, 200 parameters) orcomplete questions to generate base design and to submit a purchaseorder for the industrial device assembly. Having the processor 126determine the parameters may be efficient by reducing the number oftimes the user is queried and the time for generating a client-specificbase design and layout. The parameters may include safety attributes(e.g., arc containment), intelligence attributes (e.g., number ofintelligent control devices), system attributes (e.g., control voltage,industrial operating voltage), communication attributes (e.g., number ofpower switches), unit attributes (e.g., withdrawable units), and thelike related to the industrial device assembly.

The processor 126 may determine the parameters based on analyzing andidentifying patterns of previously specified parameters from historicaldata associated with a particular client from previous industry deviceassemblies. The historical data may be retrieved from a database thatstores information related to customer selections and preferencesrelated to generating base designs over a period of time, for pastpurchases, based on machine-learned patterns or behaviors, and the like.The database may be continuously updated each time a base design isgenerated or after a particular period of time. For example, thehistorical data may include data related to base designs previouslypurchased by a client, and other related data, such as preferences for alayout of a base design. The historical data may include, for example,safety features, such as arc containment enclosures previously purchasedby the customer. The historical data may also include particular layoutsof base designs previously purchased by the customer or otherorganizations.

As such, the process 300 may involve determining client-specificparameters to more accurately and efficiently generate client-specificbase designs. In some embodiments, the processor 126 may employ amachine-learning algorithm or an intelligent knowledge-based algorithmto analyze and identify patterns from the historical data. It can beappreciated that machine-based processing and algorithms may provideinsight that may not be attained via human analyses, by relying oncomplex data patterns/relationships that may not be conceived in thehuman mind. Further, the processor 126 may take advantage of knownpatterns and interdependencies between parameters to calculate unknownparameters via the machine-based processing and algorithms.

For example, a machine learning model may be determined based onhistorical data related to various clients from various industries andgeographic locations. The machine learning model may be updated eachtime a base design recommendation is determined, a base design ispurchased/selected, or at some other time (e.g., after a set period oftime has passed, after a set number of base designs have beengenerated). The machine learning model may be updated such thatsubsequent base designs take the most recent customer data into account.

In some embodiments, the machine learning model may also analyze howvarious users interact with generated set of base designs . For example,the generated set of base designs may be presented to a user via a webbrowser executing on a client device. The machine learning model maymonitor how the user or client interacts with the generated set of basedesigns in the web browser to analyze any changes or selections that aremade and use these inputs as feedback for further training of themachine learning model. Monitoring and adding these interactions to themachine learning model may enable the machine learning model tocontinually improve its ability to provide recommendations to users andto other organizations that share certain similarities with therespective organization.

Based on the client data (e.g., location data, and industry data) aswell as patterns determined from the historical data, the processor 126may identify parameters for the electrical components from theelectrical load list. The processor 126 may determine the type ofparameters and acceptable limits corresponding to quantitativeparameters (e.g., range for industrial operating voltage) for theelectrical components based on identifying a function corresponding toeach electrical component such that the electrical components may worktogether in the industrial automation system. That is, as base designsare generated for each area where there could be an option, theprocessor 126 may designate one of the options as a base option and maydesignate the other selections as additional options. For instance, theprocessor 126 may declare that a machine interface with a unit mayinclude a pushbutton as a base option and may include a Human InterfaceMachine (HIM) as a selectable option.

Additionally, the processor 126 may select parameters based on userhistory, geographic data, industry data, and the like. For example, theprocessor 126 may identify an industrial operating voltage for aparticular base design based on knowledge of predetermined or commonindustrial voltages used across the world and a corresponding locationof a user (e.g., client) or the particular industrial device assembly.In addition to identifying the type of parameters and correspondingoperating ranges based on particular functions of each of the electricalcomponents, the processor 126 may also identify parameters using thehistorical data based on client preference from previous selections andpurchases.

After identifying the parameters, the processor 126 may identify a setof base designs that meets the identified parameters (block 306). Asmentioned above, the database or the design library may store any numberof base designs corresponding to different clients. From the availablebase design and information in the database or the design library, theprocessor 126 may select a set of base designs that are well-suited andmeet specifications of the client data and the identified parameters.That is, the identified set of base designs are client-specific or meetclient specifications and preferences.

Parameters are used to select particular base designs based on client,geographic, and industry information as well as electrical load lists.For example, based on size and type of components (e.g., starter, drive,soft start) that meet control specifications (e.g., output voltage) of aparticular region and/or industry, a set of base designs are selected.For example, a particular selection of an overload for a motor start maycorrespond to a particular selection of base designs.

The processor 126 may use the previously mentioned machine learningalgorithm to select the set of base designs. For example, the processor126 may employ decision tree logic to determine the set of base designsfrom the base designs in the database or the design library that likelymatch the client data and the identified parameters. That is, theprocessor 126 uses the decision tree logic to filter out base designsthat do not meet specifications of the client data and the identifiedparameters. For example, a decision tree may provide respectiveprobabilities for each base design meeting the specifications of theclient data and the identified parameters. If the probability of thebase design is greater than a threshold percentage (e.g. 75%, 85%, 95%),then the processor 126 may select the base design to be a part of theset of base design that are client-specific.

In some embodiments, the processor 126 may also analyze electrical loadlimits to identify the set of base designs. The number of electriccomponents that may be placed within each unit may be dependent onelectrical load limits of respective sections and units. Positioning ofthe electric components within the physical industrial device assemblymay be limited based on physical dimensions of sections and units withinthe industrial device assembly, electrical connectivity, and otherelectrical load limits. For example, with respect to physicaldimensions, if a desired industrial device assembly includes 10 sectionseach with 20 units, the industrial device assembly may support a maximumtotal of 200 units. Further, with respect to electrical connectivity, ifa unit includes 1 electrical port that can connect to 5 devices, theunit may include no more than 5 industrial automation devices.

After the set of base designs have been identified, the processor 126may identify one or more supporting modules for each base design of theidentified set of base designs (block 308). The supporting modules mayinclude additional components that may not have been a part of theelectrical load list but may be useful in enabling certain components tooperate or allow the industrial device assembly to perform efficiently.For example, supporting modules may include mechanical stands that allowcertain devices to have a certain amount of clearance from a floor,power supply modules that ensure that a sufficient amount of regulatedvoltage is provided to a component, and the like. Additional examples ofthe supporting modules may include one or more main switches, one ormore Ethernet switches, one or more power supplies, one or more Ethernetpower supplies.

Some supporting modules may provide additional communication featuresbetween the respective components. The quantity and location of thesupporting modules within the industrial device assembly may bedetermined based on the electrical load limits. The processor 126 mayidentify the supporting modules based on determining particularfunctions of each of the electrical components and using the historicaldata based on client preference from previous selections and purchases.

With the foregoing in mind, by way of example, the processor 126 maydetermine an appropriate motor management approach (e.g., use ofstarter, drive, soft start), appropriate sizes of components that may beused to meet the control and output voltage based on a region, anindustry, or other input parameters that correspond to a particular basedesign. For instance, the processor 126 may make a selection regarding atype of overload that may be used for a particular motor starter. Theselected overload may cause the processor 126 to change thecorresponding base design selection. In this way, the algorithm forselecting components and base designs may use customer history,geographic location, industry and application information, and otherinput parameters to select the correct overload, which then may be usedto select the proper motor starter base design.

Having identified the parameters, the set of base designs, and thesupporting modules, the processor 126 may then display the set of basedesign and corresponding supporting modules to the client via the GUI(block 310). Each base design may be represented as one or moreselectable visualizations (e.g., images). In some embodiments, each basedesign may be represented as a thumbnail on the GUI. Further, each basedesign includes data related to the parameters, a model of each of theelectrical components, a lineup of the electrical components, a leadtime, a catalog number, a cost, a description, a name, a relatedindustry, and other information for the industrial device assembly.

After viewing the set of the base designs displayed via the GUI, theuser may select a visualization associated with a particular basedesign. That is, the processor 126 may receive a selection of a basedesign as input from the client (block 312). Based on the selected basedesign, the processor 126 may dynamically generate a layout associatedwith the base design (block 314).

In some embodiments, the layout may be an overview, a horizontal view, avertical view of the placement of the electrical components within theindustrial device assembly and corresponding electrical connections andcommunication links between the electrical components. In particular,the layout may be a graphical representation of the positioning of eachelectrical component within the physical industrial device assemblybased on the selected base design. In some embodiments, the layout mayinclude, a single-line view, and an elevation view of the electricalcomponents. The processor 126 may dynamically display the layout to theuser via the GUI (block 316) with the selection of the base design. Inadditional and/or alternative embodiments, the processor 126 may receiveinput from the user to generate a particular layout.

With the preceding in mind, FIG. 9 illustrates a flow chart of a process330 for dynamically generating single-line drawings, elevation drawings,and engineering documents based on the base design selected by the user.The process 330 may be performed by any suitable system that may receiveinput via a GUI and instruct a processor to generate and displaysingle-line drawings, elevation drawings, and engineering documentsbased on the base design selected by the user. While the process 300 isdescribed using steps in a specific sequence, it should be understoodthat the present disclosure contemplates that the described steps may beperformed in different sequences than the sequence illustrated, andcertain described steps may be skipped or not performed altogether. Insome embodiments, the process 300 may be implemented by executinginstructions stored in a tangible, non-transitory, computer-readablemedium, such as the memory device 128, using a processor, such as theprocessor 126.

Blocks 302 to 316 from FIG. 8 correspond in description with blocks 332to 346 in FIG. 9, respectively. After the layout based on the basedesign has been generated, the user may also have the option to view asingle-line drawing, an engineering drawing, and/or an engineeringproposal document via the GUI. As such, according to block 348, theprocessor 126 may receive user input via the GUI to generate thesingle-line drawing, the engineering drawing, and/or the engineeringproposal document. As mentioned above in FIG. 1, the single-line drawingsingle-line diagram may be a visual representation of the industrialdevice assembly. The industrial device assembly be complex and thesingle-line drawing provides a simplified visual representation of theindustrial device assembly in two-dimensions. To generate thesingle-line diagram, a single-line engine may generate a graphicalobject for each of the electrical components in the industrial deviceassembly. The graphical objects may be generated using scalable vectorgraphics.

Like the single-line drawing, the elevation drawing is simplified visualrepresentation of the industrial device assembly in two-dimensions, butthe elevation drawing depicts dimensions such as height, length, andwidth of the industrial device assembly and corresponding electricalcomponents. Further, the engineering proposal document may include adetailed description of the base design and the identified parameters.In some embodiments, the engineering proposal document may includeaggregate base design information (e.g., the detailed description of thebase design and the identified parameters, the single-line drawing, theelevation drawing, the layout). In response to receiving user input, theprocessor 126 may display one or more visualizations that represent thesingle-line drawing, the elevation drawing, and/or the engineeringproposal document (block 350).

Visual and textual representation within the single-line drawing, theelevation drawing, and/or the engineering proposal document may belinked to each other or configured as interactive objects that cause theprocessor 126 to provide additional information regarding the objectthat corresponds to the visual and/or textual representation. That is, agraphical object representing an electrical component in the single-linedrawing may be linked to or used to access a visualization representingthe electrical component in the elevation drawing. As such, the visualand/or textual representations may include metadata or may be associatedwith a software pointer that links the respective representation toother objects in one medium to corresponding objects other mediums. Inaddition, the graphical object of the single-line drawing and thevisualization of the elevation drawing may correspond to a descriptionof the electrical component in the engineering proposal document. Insome embodiments, the user may search for information related to aparticular electrical component via the GUI. The processor 126 mayidentify representations of the particular electrical components andhighlight those representations in the layout, the single-line drawing,the elevation drawing, the engineering proposal document, and the likein the search result that is presented to the user.

Further, because features of the layout, the single-line drawing, theelevation drawing, the engineering proposal document are linked to eachother, the processor 126 may dynamically update any of the featuresrepresented on each document or drawings in an efficient manner. Forexample, if the processor 126 receives an input of modification to anelectrical component from the electrical load list, the processor 126may update the electrical component within the base design, the layout,the single-line drawing, the elevation drawing, the engineering proposaldocument, and the like without independently changing inputs for eachrespective document. Furthermore, a change to an electrical componentwithin the layout, the single-line drawing, the elevation drawing, theengineering proposal document also be automatically applied to othervisualizations. For example, a change to an electrical component withinthe layout is automatically reflected as a similar change to theelectrical component in the single-line drawing, the elevation drawing,and the engineering proposal document. This change or update can be seenby the user in response to the processor 126 receiving an input forgenerating the single-line drawing, the elevation drawing, and/or theengineering proposal document.

The widgets depicted on the GUI may provide interactive input componentsthat the user may select to generate the single-line drawing, theelevation drawing, and/or the engineering proposal document. As such,FIG. 10 illustrates GUI 360 that displays the options for generating thesingle-line drawing, the elevation drawing, and/or the engineeringproposal document. For example, the GUI 360 may include a set of widgets362. Selecting a respective widget from the set of widgets 362 mayresult in generating a summary of information related to the basedesign, saving information displayed on the GUI 360, generating thesingle-line drawing, generating the elevation drawing, generating theengineering proposal, and the like. In some embodiments, the single-linedrawing, the elevation drawing, and/or the engineering proposaldocuments may be exported as PDFs or any suitable file type by the user.

FIG. 11 illustrates a GUI 390 that depicts information related to theselected base design. The panel 396 depicts a brief lineup summary ofthe industrial device assembly while the panel 394 depicts a briefdescription of each electrical component within the industrial deviceassembly. The panel 396 includes a total cost of the industrial deviceassembly, while the panel 394 may include an individual cost of eachelectrical component or unit within the industrial device assembly (notshown in FIG. 11). In some embodiments, the panel 396 may depictinformation for each unit, and the panel 396 may be organized, such thatsimilar units of the industrial device assembly have been groupedtogether. Selecting a button from the set of buttons 392 corresponds tovarious actions. For example, selecting the “request engineering packet”allows the user to download a file containing a title page, thesingle-line drawing, the elevation drawing, and other schematicsassociated with the selected base design or lineup. Selecting the“request draft proposal” allows the user to download a file containing abrief summary of the base design and information related to thepurchasing process of the manufacturer. Further, selecting the “requestquote” allows the user to send the manufacturer a request for receivinga fixed price proposal.

As mentioned above, the database or the design library may store anynumber of base designs corresponding to different clients (e.g., 1000base designs). From the available base design and information in thedatabase or the design library, the processor 126 may select a set ofbase designs that are well-suited and meet specifications of particularclient and the identified parameter. That is, the identified set of basedesigns are client-specific or meet client specifications andpreferences. However, if the processor is unable to identify or generateclient-specific set of base designs, then the processor 126 may providethe user with predefined set of base designs.

FIG. 12 illustrates a flow chart of a process 420 for providingpredefined base designs, according to one embodiment. The process 420may be performed by any suitable system that may instruct a processor toprovide predefined base designs via a GUI. While the process 420 isdescribed using steps in a specific sequence, it should be understoodthat the present disclosure contemplates that the described steps may beperformed in different sequences than the sequence illustrated, andcertain described steps may be skipped or not performed altogether. Insome embodiments, the process 420 may be implemented by executinginstructions stored in a tangible, non-transitory, computer-readablemedium, such as the memory device 128, using a processor, such as theprocessor 126.

Blocks 302 and 304 from FIG. 8 correspond in description with blocks 422and 424 in FIG. 12, respectively. After determining the parameters inblock 424, the processor 126 may determine whether any of the availablebase designs meet any of the parameters based on the client data (block426). That is, the processor 126 may query the design library toidentify existing base designs that correspond to the parametersdetermined at block 424. If the processor 126 is able to find a set ofbase designs that has more than a threshold percentage of the parameters(e.g., threshold percentage such as 75%, 85%, or 95%), then theprocessor 126 may identify and provide the user with client-specificbase designs (block 428). These client-specific base designs are similarto the set of base design identified in block 306 of FIG. 8. However, ifthe processor 126 is unable to find a set of base designs that meets theparameters, then the processor 126 may identify and provide the userwith predefined base designs (block 430) to manage the industrial deviceassembly (e.g., MCC).

Predefined based designs may be generated based on available base designfrom previous industrial device assemblies associated with otherclients, industries, or the like and/or based on technical knowledge ofsales and engineering staff. Predefined base designs may correspond toan expected set of electrical components that would be included forstarting and/or managing motor operations. As such, by way of example,the base designs may include a core starter, a drive or a soft starter,and a number of components used to support those components (e.g.,breakers, overload relay, cooling, etc.). As such, the predefined basedesign may be defined by a load type and size and may be further refinedby core components that affect components of a corresponding electricaldesigns (e.g., voltage, maximum current) and mechanical designs (e.g.,dimensions). As such, base design may also include electrical andmechanical engineering documentation that detail the electrical designand the mechanical design aspects of the industrial equipment assembly.

Keeping this in mind, if the processor 126 is unable to identify basedesigns from the database or the design library for a particular clientor generate a set of base designs for the particular client, then theprocessor 126 may select a predefined base design that is similar inindustry, location, or other features related to the particular client.The features may include the type of product being produced by theclient, a type of process being performed by the client, a set ofregulations associated with the client, and the like. While thepredefined base design may not be fully representative of the identifiedparameters like a client-specific base design, the predefined basedesign may be partially representative of the identified parametersparticular to the client. For example, given the particular client isform the oil and gas industry, the processor 126 may provide predefinedbase designs related to the oil and gas industry. In this way, a usermay then customize the predefined base design to accommodate itsparticular functions.

As briefly discussed above, after the processor 126 identifies the setof base designs, the processor 126 may also add any supporting modulesto the set of base design. Non-limiting examples of the supportingmodules may include one or more main switches, one or more Ethernetswitches, one or more main power supplies, one or more Ethernet powersupplies. In some embodiments, rather than adding the supporting modulesto each base design with the set of base design, the processor 126 mayautomatically add any supporting modules (e.g., Ethernet module) to theselected base design.

Generating Ethernet Power Modules for Selected Base Designs

As such, FIG. 13 illustrates a flow chart of a process 450 forgenerating Ethernet power modules based on the selected base design,according to one embodiment. The process 450 may be performed by anysuitable system that may instruct a processor to determine a quantityand location of Ethernet modules to be placed within the layout. Whilethe process 450 is described using steps in a specific sequence, itshould be understood that the present disclosure contemplates that thedescribed steps may be performed in different sequences than thesequence illustrated, and certain described steps may be skipped or notperformed altogether. In some embodiments, the process 450 may beimplemented by executing instructions stored in a tangible,non-transitory, computer-readable medium, such as the memory device 128,using a processor, such as the processor 126.

Block 302 from FIG. 8 corresponds in description with block 452 in FIG.12. After receiving the selected base design, the processor 126 maycalculate the electrical load limits based on physical dimensions (e.g.,length, width, height), number, and location of sections and units inthe selected base design (block 454). As mentioned above, the industrialdevice assembly may be subdivided into lineups, sections, columns,units, modules, or the like. Each lineup may have 1-N sections and eachsection may have 1-M units, which respectively contain at least oneindustrial automation device or control device.

The number of Ethernet switch devices and Ethernet power supply unitsthat may be placed within each unit may be dependent on electrical loadlimits of respective sections and units. That is, the components orcontrol devices (e.g., units) positioned in a particular section may becommunicatively coupled to one or more Ethernet switch devices, whichmay include one more Ethernet switch power supply units. Based on thenumber of components in the section, the processor 126 may determine anumber of Ethernet switch devices that may be used to facilitateconnectivity to each of the components. That is, since each Ethernetswitch device may include a limited number of ports, the number ofEthernet switch devices may relate to the number of components that areto be connected to the devices. In turn, based on the electrical loadlimits and the number of Ethernet switch devices determined by theprocessor 126, the processor 126 may determine a number of Ethernetswitch power supplies that will be used to power the Ethernet switchdevices. In some embodiments, different Ethernet switch power suppliesmay be rated for different power wattages and voltages, such that alimited number of Ethernet switch devices may be coupled to eachEthernet switch power supply. The processor 126 may account for thesepower characteristics when determining a number of Ethernet powersupplies to use for the number of Ethernet switch devices

In addition, the processor 126 may use the layout of the section inwhich the Ethernet switch devices and the Ethernet switch power suppliesand the dimensions of the same to determine a number of the Ethernetswitch devices and Ethernet switch power supplies to use to provideconnectivity to the components in the respective section. That is,positioning of the Ethernet switch devices and Ethernet power supplyunits within the physical industrial device assembly may be limitedbased on physical dimensions of sections and units within the industrialdevice assembly, electrical connectivity, and other electrical loadlimits. For example, with respect to physical dimensions, if a desiredindustrial device assembly includes 10 sections each with 20 units, theindustrial device assembly may support at most a total of 200 units.Further, with respect to electrical connectivity, if a unit includes 1Ethernet port that can connect to 5 Ethernet devices, the unit mayinclude no more than 5 Ethernet switch devices.

Based on the calculated electrical load limits and other factorsdiscussed above, the processor 126 may determine the number and locationof the Ethernet switch devices and Ethernet power supply units to beplaced in each section and unit of the physical industrial deviceassembly (block 456). The processor 126 may also take into considerationwhich electrical components are Ethernet-enables when determining thenumber and location of the Ethernet switch devices and Ethernet powersupply units for placement within each unit of a section.

In turn, the processor 126 may display the Ethernet switch devices andEthernet power supply units placed in respective sections and units withrespect to the selected base design on a layout (block 458). Asmentioned above, the layout is a graphical representation of thepositioning of each electrical component within the physical industrialdevice assembly based on the selected base design. In some embodiments,the layout may also include single-line drawings and elevation drawings.

If the processor 126 identifies a modification to an Ethernet switchdevice or Ethernet power supply, the processor 126 may update the basedesign, the layout, the single-line drawing, the elevation drawing, theengineering proposal document, and the like to reflect the modification.Furthermore, a change to an Ethernet switch device or an Ethernet powerdevice in one graphical representation may also automatically applied toother visualizations. For example, a change to an Ethernet switch devicewithin the single-line drawing may be automatically reflected as asimilar change to the Ethernet switch device in the elevation drawing.This change or update can be seen by the user in response to theprocessor 126 receiving an input for generating the single-line drawingand/or the elevation drawing.

Generating Selectable Visulizations for Base Designs

In some embodiments, the processor 126 may present selectable basedesigns and other options via a guided selling technique in auser-friendly and efficient manner. Option packs represent additionalselectable functional groups associated with each base design. Theoption packs may be grouped based on particular parameters (e.g., safetyattributes, system attributes, intelligence attributes, unit attributes)for each base design. As such, FIG. 14 illustrates a flow chart of aprocess 480 for generating option packs associated with the selectedbase design, according to one embodiment.

The process 480 may be performed by any suitable system that mayinstruct a processor to determine option packs associated with selectedbase design. While the process 480 is described using steps in aspecific sequence, it should be understood that the present disclosurecontemplates that the described steps may be performed in differentsequences than the sequence illustrated, and certain described steps maybe skipped or not performed altogether. In some embodiments, the process480 may be implemented by executing instructions stored in a tangible,non-transitory, computer-readable medium, such as the memory device 128,using a processor, such as the processor 126.

Block 302 from FIG. 8 corresponds in description with block 482 in FIG.12. After receiving the selected base design, the processor 126 mayidentify one or more option packs for the selected base design (block484). The processor 126 may identify the one or more option packs basedon client data (e.g., electrical load list, industry data, locationdata). An option pack may include a set of additional attributes orcomponents (e.g., push button, HMI, actuator, operator station) relatedto the selected base design that are categorized based on similarfunctionalities. By way of example, an operator station, arc faultcontainment safety features, and communication options may be added tothe selected base design as option packs. In any case, option packsallow for changes to the base design without impacting core electricaland mechanical designs of the base design. Further, option packs providefunctional value to customers and sales staff associated with theindustrial device assembly by grouping together components based onsimilar attributes, as opposed to using part number inputs. Theseadditional, optional attributes may be categorized based on safety,system, intelligence, unit, and so forth. The safety option pack mayinclude attributes such as arc containment, types of emergencyequipment, and so forth. The intelligence option pack may include, forexample, types of intelligent control devices. The system option packmay include attributes such as an industrial operating voltage, acontrol voltage, a line voltage, a line frequency, a type of line cableentry, types of buses, withstand rating, main current capacity, type ofenclosure, percentage of load utilization, a location for load cableexit, a future unit space, and the like. The unit option pack mayinclude attributes related to the size and weight of each electricalcomponent.

The option packs available to a user may vary based on the selected basedesign and client data. For example, if the industry data indicates thatthe client (e.g., user) is from the oil and gas industry, the processor126 may identify the one or more option packs related to the safetyattributes. That is, if the industry guards itself from exceedingcertain temperatures for various components in oil and gas manufacturingplants, the processor 126 may determine one or more safety option packsto add to the base design in order to address these potentialsituations.

After identifying the one or more options packs (e.g., safety optionpack, communication option pack, intelligence option pack), theprocessor 126 may display the one or more option packs as one or moreselectable visualization (block 486). Each option pack may correspond toa selectable visualization. In some embodiments, the selectablevisualization may be a widget with a sliding feature (e.g., slidingwidget). The sliding widget may include any number and types of levels.By way of example, the sliding widget may include 3 different levels(e.g. wide or broad level, intermediate level, advanced or narrow level)associated with varying degrees of features associated with theelectrical components. At block 486, the processor may have identifiedand subsequently displayed a level corresponding with each option pack.

In some embodiments, the processor 126 may determine a level for eachoption pack based on historical data associated with the client fromprevious industry device assemblies. Such historical data for eachclient and corresponding previous industry device assemblies may bestored in a database or a device library that is accessible by theprocessor 126. The database or device library may include informationrelated to the client data, identified parameters associated with theselected base design, supporting modules, layouts, single-line drawings,elevation drawings, engineering proposal documents, and the like foreach client for each industry device assembly. Further, the processor126 may employ a machine-learning algorithm or an intelligentknowledge-based algorithm to analyze and identify patterns from thehistorical data to determine the level for each option pack.

The levels of the sliding widget may be configured to slidebidirectionally by the user. That is, by moving the sliding widget inone direction, the levels may relatively increase or decrease ingranularity. The levels tend to increase in granularity as the slidingwidget slides from the left end of the sliding bar to the right end ofthe sliding bar. For example, the left end of the bar may correspond toa broad or wide level while the right end corresponds to an advanced ornarrow level. In response to the user selecting a broad or wide level inan options pack, the processor 126 may identify overarching parametersfor multiple components within the industrial device assembly. That is,the processor 126 may define a minimum number of parameters (e.g., 3, 5,7 parameters) for each component of the multiple components within theindustrial device assembly. Further, in response to the user selecting anarrow or advanced level in an options pack, the processor 126 mayidentify particular parameters for an individual component within theindustrial device assembly. That is, the processor 126 may define amaximum number of parameters (e.g., 10, 20, 50 parameters) for theindividual component. For example, the with respect to the narrow oradvanced level, the processor 126 may identify every particularparameter of a software module used to control operating conditions of asingle component within the industrial device assembly. The middleportion of the bar may correspond to an intermediary level. Afterviewing the one or more option packs and corresponding levels, whichwere automatically determined by the processor, on the GUI, the user maylike to change a level associated with an option cap. In general, anoptions pack associated with an advanced, narrow level may be moreexpensive compared to options packs with a broad or wide level.Therefore, given that the identified parameters of the selected basedesign and corresponding supporting modules remain constant, a clientmay save money by selecting an option pack with a wider level comparedto a narrower level .

Based on the one or more option packs presented to the user, the usermay select particular option pack and change corresponding levels. Itcan be appreciated that a selectable visualization such as the slidingwidget may be a user-friendly mechanism to receive inputs from the userregarding the one or more option packs. The sliding widgets reduces thenumber of inputs submitted by the user. Rather than the user having tocomplete numerous questions or defining each specification, theprocessor 126 may identify parameters for the one or more option packsbased on limited number of inputs from the user.

In response to receiving a selection of the one or more option packs viauser input (block 488), the processor 126 may identify parametersassociated with the selected one or more option packs (block 490). Asmentioned above, the parameters may include safety attributes (e.g., arccontainment), intelligence attributes (e.g., type of intelligent controldevices), system attributes (e.g., industrial operating voltage), unitattributes (e.g., withdrawable units), and the like related to theindustrial device assembly. The processor 126 may identify parametersfor the selected base designs based on determining the function of eachof the electrical components in the selected base design, overallfunction of the industrial device assembly, and electrical load limitsof respective sections and units. The identified parameters correlatewith each base design and corresponding option packs. Based on theindustry and regions of operating the industrial device assembly, theprocessor 126 may identify one or more safety option packs. For example,if the industry guards itself from exceeding certain temperatures forvarious components in oil and gas manufacturing plants, the processor126 may determine one or more safety option packs (e.g., arccontainment) to add to the base design in order to address thesepotential situations

Further, based on patterns from prior historical data and the electricalload limits of respective sections and units, the processor maydetermine system and unit option packs. For example, based on the numberof electrical components and corresponding electrical connections andoperating ranges, the processor 126 may determine system and unitparameters. For example, given minimum and maximum operating andphysical dimension limits of the industrial device assembly, theprocessor 126 may identify, for example, industrial operating voltage, acontrol voltage, a line voltage, and size of electrical componentswithin the industrial device assembly. By way of example, with respectto the unit options pack and based on the number of electricalcomponents in each unit, the processor 126 may determine a number ofavailable electrical ports that may be used to facilitate connectivityto each of the electrical components. The processor 126 may determineintelligence option packs based on determining the type of electricalcomponents within the industrial device assembly and function of theindustrial device assembly. For example, the processor 126 may determinethe type of intelligent control devices to include in an intelligenceoption pack in order to improve operating efficiency of the industrialdevice assembly and corresponding electrical components.

As mentioned above, in some embodiments, the processor 126 may determinethe parameters based on analyzing each level corresponding to an optionpack and identifying patterns from historical data associated with aparticular client purchases, preferences from previous industry deviceassemblies, and/or technical knowledge of sales and engineering staffassociated with the industrial device assemblies. In some embodiments,the processor 126 may employ a machine-learning algorithm or anintelligent knowledge-based algorithm to analyze and identify patternsfrom the historical data. It can be appreciated that machine-basedprocessing and algorithms may provide insight that may not be attainedvia human analyses, by relying on complex data patterns/relationshipsthat may not be conceived in the human mind. Further, the processor 126may take advantage of known patterns and interdependencies betweenparameters to calculate unknown parameters via the machine-basedprocessing and algorithms.

After identifying the parameters, the processor 126 may update theselected base design based on the selected one or more option packs. Inturn, the processor 126 may display the updated base design based on theselection of the one or more options packs to the client via the GUI(block 492). The updated base design and corresponding option packs maybe represented in a layout, a single-line diagram, an elevation drawing,an engineering proposal document, and the like. In some embodiments, theuser may able to update selections of the one or more option packs andcorresponding parameters, even after the updated base design with theone or more option packs has been generated. For example, in response toreceiving a modification to a parameter associated with an option pack,the processor 126 may automatically update the option pack andcorresponding base design.

With the guided selling technique in mind from FIG. 14, FIG. 15illustrates a GUI 510 that depicts selectable inputs for submittingclient data, according to one embodiment. For example, the GUI 510includes inputs for industry, installation location (shown as drop-downmenus). While some inputs may be drop-down menus, other inputs may allowtext submission. As indicated by the asterisk (*), some of the inputsdisplayed on the GUI 510 may be required before a set of base designscan be generated. The base design and the one or more option packs havenot been generated by a processor (e.g., the processor 126) as indicatedby the GUI 510 since the client data had not been submitted by the user.

After the client data and the selected base design has been received bythe processor, the processor 126 may generate and display one or moreoption packs corresponding to the selected base design. As such FIG. 16illustrates a GUI 540 that depicts a sliding widget associated with anoption packs, according to one embodiment. Based on inputs such asindustry 542 (e.g., oil and gas), installation location 544 (e.g.,China), sold to customer, end customer, and the like, the processor mayidentify an option pack and set a level based on the inputs (as shown bythe sliding widget 548). For a safety option pack 546, a processor(e.g., the processor 126) may have determined the level to beintermediate based on the inputs from the client. As mentioned above,the processor 126 may determine a level associated with an option packbased on the client data as well any identified patterns from historicaldata associated with the client from previous industry deviceassemblies. For example, safety attributes may vary amongst variousregions and industries. After the user has selected the one or moreoption pack and verified or changed corresponding levels, the processormay automatically populate fields representing parameters of the safetypack option 546 (as shown by 550).

In turn, FIG. 17 illustrates a GUI 570 that depicts the identifiedparameters associated with an option pack. In the GUI 570, parameters572 have been identified and displayed by a processor (e.g., theprocessor 126) for a system option pack 570. The system option pack 570may include identified parameters 572 related to an industrial operatingvoltage, a control voltage, a line voltage, a line frequency, a type ofline cable entry, types of buses, withstand rating, main currentcapacity, type of enclosure, percentage of load utilization, a locationfor load cable exit, a future unit space, and the like. Additionally,the processor 126 may also determine and present calculated options 574(e.g., main circuit breaker rating, main circuit protection type,horizontal bus rating, main circuit breaker lineup position) for thesystem option pack 570.

With the above in mind, FIG. 18 illustrates a GUI 590 that indicates aselection of one or more option packs from the one or more option packsidentified by the processor, according to one embodiment. The left panelof the GUI 590 represents a collapsible menu associated with theselected base design information. At 596 on the GUI 590, prices for oneor more option packs that have been identified by a processor (e.g., theprocessor 126) are displayed. In some embodiments, 596 may alsoillustrate prices for one or more options packs that have been selectedby the user after the processor 126 has identified the one or moreoption packs. The GUI 590 illustrates motor details, unit details, andnameplates associated with the selected base design at 594.Additionally, 594 depicts alternative base designs, which will bediscussed below.

FIG. 19 illustrates a GUI 620 for swapping the selected base design withanother base design, according to one embodiment. The GUI 620 portraysavailable alternative base designs with descriptions. If the user wouldlike to change the selected base design, the user may select a swapbutton 622 corresponding to the alternative base design that the usewould like to swap the selected base design with.

In summary, embodiments described herein provide a real-time renderingof selected base design and corresponding option packs, supportingmodules, and layout (e.g., single-line drawing) which are updatedthroughout a lifecycle of an industrial automation project. For example,using an intelligent, knowledge-based algorithm, a computing system mayprovide, via a graphical user interface (GUI), various selectable basedesigns and option packs to the customer based on customer inputs. Bypresenting selectable visualizations that correspond to base designs,the customer bypasses having to define each specification and completingnumerous questions related to the industrial automation project tosubmit a purchase order for a particular industrial device assembly.

While only certain features of the disclosure have been illustrated anddescribed herein, many modifications and changes will occur to thoseskilled in the art. It is, therefore, to be understood that the appendedclaims are intended to cover all such modifications and changes as fallwithin the true spirit of the present disclosure. The techniquespresented and claimed herein are referenced and applied to materialobjects and concrete examples of a practical nature that demonstrablyimprove the present technical field and, as such, are not abstract,intangible or purely theoretical. Further, if any claims appended to theend of this specification contain one or more elements designated as“means for [perform]ing [a function] . . . ”or “step for [perform]ing [afunction] . . . ”, it is intended that such elements are to beinterpreted under 35 U.S.C. 112(f). However, for any claims containingelements designated in any other manner, it is intended that suchelements are not to be interpreted under 35 U.S.C. 112(f).

The invention claimed is:
 1. A method, comprising: receiving, via aprocessor, a selection of a visualization via a user input, wherein thevisualization represents a base design for an industrial deviceassembly; calculating, via the processor, one or more electrical loadlimits for one or more sections of the base design based on one or moredimensions of the one or more sections, a quantity of the one or moresections, a location of the industrial device assembly, or anycombination thereof; determining, via the processor, a number ofEthernet switch devices for the one or more sections based on the one ormore electrical load limits; determining, via the processor, one or moreplacements within the base design for one or more Ethernet switchdevices of the number of Ethernet switch devices; and presenting, viathe processor, a layout of the industrial device assembly via a display,wherein the layout is indicative of: the number of Ethernet switchdevices for the one or more sections; and the one or more placements ofthe one or more Ethernet switch devices with respect to the base design.2. The method of claim 1, comprising: determining, via the processor, anadditional number of Ethernet power supply units for the one or moresections based on the one or more electrical load limits; determining,via the processor, one or more additional placements within the basedesign for one or more Ethernet power supply units of the additionalnumber of Ethernet power supply units; and presenting, via theprocessor, the layout of the industrial device assembly via the display,wherein the layout is indicative of: the additional number of Ethernetpower supply units for the one or more sections; and the one or moreadditional placements of the one or more Ethernet power supply unitswith respect to the base design.
 3. The method of claim 2, whereindetermining, via the processor, the additional number of Ethernet powersupply units comprises: calculating a third number of Ethernet portswithin each section of the one or more sections; and determining theadditional number of Ethernet power supply units based on the thirdnumber of Ethernet ports.
 4. The method of claim 1, wherein determining,via the processor, the number of Ethernet switch devices comprises:calculating a third number of Ethernet ports within each section of theone or more sections; and determining the number of Ethernet switchdevices based on the third number of Ethernet ports.
 5. The method ofclaim 1, wherein the industrial device assembly comprises a plurality ofelectrical components, and wherein the layout comprises a graphicalrepresentation indicative of a plurality of positions associated withthe plurality of electrical components within the industrial deviceassembly.
 6. The method of claim 5, wherein the graphical representationcomprises a scalable vector graphic object for each of the plurality ofelectrical components within the industrial device assembly.
 7. Themethod of claim 1, wherein the layout comprises one or more single-linedrawings, one or more elevation drawings, or both.
 8. The method ofclaim 7, comprising: receiving a first input to modify at least one ofthe one or more placements of the one or more Ethernet switch devices onthe one or more single-line drawings; updating the one or moresingle-line drawings based on the at least one of the one or moreplacements of the one or more Ethernet switch devices; and updating theone or more elevation drawing based on the at least one of the one ormore placements of the one or more Ethernet switch device in response tothe one or more single-line drawings being updated.
 9. The method ofclaim 1, comprising: receiving a modification to the number of Ethernetswitch devices via the user input; generating an updated layout based onthe modification; and presenting the updated layout via the display. 10.A system, comprising: a processor; and a memory storing instructionsthat, when executed by the processor, cause the processor to performoperations comprising: receiving a selection of a visualization via auser input, wherein the visualization represents a base design for anindustrial device assembly; calculating one or more electrical loadlimits for one or more sections of the base design based on one or moredimensions of the one or more sections, a quantity of the one or moresections, a location of the industrial device assembly, or anycombination thereof; determining a number of Ethernet switch devices forthe one or more sections based on the one or more electrical loadlimits; determining one or more placements within the base design forone or more Ethernet switch devices of the number of Ethernet switchdevices; and presenting a layout of the industrial device assembly via adisplay, wherein the layout is indicative of: the number of Ethernetswitch devices for the one or more sections; and the one or moreplacements of the one or more Ethernet switch devices with respect tothe base design.
 11. The system of claim 10, wherein the base designcomprises data related to a model, a lineup of a plurality of electricalcomponents, a lead time, a catalog number, a cost, a description, aname, a related industry, or any combination thereof for the industrialdevice assembly.
 12. The system of claim 10, wherein the industrialdevice assembly comprises a plurality of electrical components, andwherein the layout comprises a graphical representation indicative of aplurality of positions associated the plurality of electrical componentswithin the industrial device assembly.
 13. The system of claim 12,wherein the operations comprise determining electrical connectivitybetween each of the plurality of electrical components based ondetermining the number of Ethernet switch devices for the one or moresections.
 14. The system of claim 10, wherein the operations comprise:determining an additional number of Ethernet power supply units for theone or more sections based on the one or more electrical load limits;determining one or more additional placements within the base design forthe one or more Ethernet power supply units of the additional number ofEthernet power supplies; and presenting the layout of the industrialdevice assembly via the display, wherein the layout is indicative of:the additional number of Ethernet power supply units for the one or moresections; and the one or more additional placements of the one or moreEthernet power supply units with respect to the base design.
 15. Thesystem of claim 14, wherein determining the additional number ofEthernet power supply units comprises: calculating a third number ofEthernet ports within each section of the one or more sections; anddetermining the number of Ethernet power supply units based on the thirdnumber of Ethernet ports.
 16. The system of claim 10, whereindetermining the number of Ethernet switch devices comprises: calculatinga third number of Ethernet ports within each section of the one or moresections; and determining the number of Ethernet switch devices based onthe third number of Ethernet ports.
 17. The system of claim 10, whereinthe operations comprise: receiving a modification to the number ofEthernet switch devices via the user input; generating an updated layoutbased on the modification; and presenting the updated layout via thedisplay.
 18. A non-transitory computer-readable medium storinginstructions that, when executed by a processor, cause the processor toperform operations comprising: receiving, via the processor, a selectionof a visualization via a user input, wherein the visualizationrepresents a base design for an industrial device assembly; calculating,via the processor, one or more electrical load limits for one or moresections of the base design based on one or more dimensions of the oneor more sections, a quantity of the one or more sections, a location ofthe industrial device assembly, or any combination thereof; determining,via the processor, a number of Ethernet switch devices for the one ormore sections based on the one or more electrical load limits;determining, via the processor, one or more placements within the basedesign for one or more Ethernet switch devices of the number of Ethernetswitch devices; and presenting, via the processor, a layout of theindustrial device assembly via a display, wherein the layout isindicative of: the number of Ethernet switch devices for the one or moresections; and the one or more placements of the one or more Ethernetswitch devices with respect to the base design.
 19. The non-transitorycomputer-readable medium of claim 18, wherein the layout comprises oneor more single-line drawings, one or more elevation drawings, or both.20. The non-transitory computer-readable medium of claim 19, wherein theoperations comprise: receiving a first input to modify at least one ofthe one or more placements of the one or more Ethernet switch devices onthe one or more single-line drawings; updating the one or moresingle-line drawings based on the at least one of the one or moreplacements of the one or more Ethernet switch devices; and updating theone or more elevation drawing based on the at least one of the one ormore placements of the one or more Ethernet switch device in response tothe one or more single-line drawings being updated.